q-Measurement Scheme set in Quantum Photonic Frameworks: Linking Abstract Space and Lab Spaces

TL;DR

This paper proposes a novel quantum measurement scheme linking abstract and laboratory spaces using a framework that redefines particle concepts and introduces connectors as bridges between quantum and classical regions.

Contribution

It introduces a new q-measurement framework that connects abstract quantum states with laboratory observations through innovative linking mechanisms.

Findings

A new theory for quantum measurement based on space linking.

Redefinition of particle and energy concepts in measurement.

Framework incorporates quantum information ideas.

Abstract

Beginning in abstract space and dislodging the representational form paves a way to formulate a version of a quantum physical measurement scheme. With materiality playing sustainment roles with respect to q-states, these latter control system response towards external probes. Sustainment concerns all possible q-states. The particle character usually assigned to eigenstates and eigenvalues dies out, while energy gaps relate to possible energy quanta exchanges; the occupancy concept no longer required. Abstract and laboratory spaces are incommensurate, linking them leads to a possible physical q-measurement theory. Connectors (links) are referred to as gangplanks and/or gangways, they perform in frontiers arbitrating quantum to classical regions. Inertial frames facilitate linking q-state domains via projection to wave function space. A physical quantum measurement theory obtains grounded on these elements including quantum information concepts.